A pressure sensor device with a mems piezoresistive pressure sensing element attached to an in-circuit ceramic board comprises a monolithic ceramic circuit board formed by firing multiple layers of ceramic together. The bottom side of the circuit board has a cavity, which extends through layers of material from the ceramic circuit board is formed. A ceramic diaphragm, which is one of the layers, has a peripheral edge. The diaphragm's thickness enables the diaphragm bounded by the edge to deflect responsive to applied pressure. A mems piezoresistive pressure sensing element attached to the top side of the ceramic circuit board generates an output signal responsive to deflection of the ceramic diaphragm. A conduit carrying a pressurized fluid (liquid or gas) can be attached directly to the ceramic circuit board using a seal on the bottom of the ceramic circuit board, which surrounds the opening of the cavity through the bottom.
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1. A mems piezoresistive pressure sensor device comprising:
a ceramic circuit board having a top side and a bottom side, the bottom side having a cavity, which extends through the ceramic circuit board to a ceramic diaphragm having a peripheral edge, the ceramic diaphragm having a thickness selected to enable the ceramic diaphragm to deflect responsive to an applied pressure;
a mems piezoresistive pressure sensing element attached to the top side of the ceramic diaphragm by a layer of glass frit, the mems piezoresistive pressure sensing element being substantially centered over the ceramic diaphragm peripheral edge, the mems piezoresistive pressure sensing element configured to generate an output signal responsive to deflection of the ceramic diaphragm.
2. The pressure sensor device of
3. The pressure sensor device of
4. The pressure sensor device of
5. The pressure sensor device of
6. The pressure sensor device of
7. The pressure sensor device of
8. The pressure sensor device of
9. The pressure sensor device of
10. The pressure sensor device of
11. The pressure sensor device of
13. The pressure sensor device of
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A cavity 108 extends upwardly through the port 102 and is “closed” at a top side 116 by a thinned area or portion 110, above which is a conventional MEMS silicon pressure sensing element 112. Prior art MEMS silicon pressure sensing elements are disclosed in U.S. Pat. No. 6,427,539 entitled, “Strain gauge,” U.S. Pat. No. 8,302,483 entitled, “Robust design of high pressure sensor device,” and U.S. Pat. No. 8,171,800 entitled, “Differential pressure sensor using dual backside absolute pressure sensing,” to name a few, the contents of which are incorporated herein by reference.
The thinned portion 110 has a thickness that is about 0.3 mm to about 0.4 mm. It acts as a diaphragm, deflecting upwardly and downwardly responsive to changes in the pressure of a fluid in the cavity 108.
The thinned portion 110 is generally planar. The cavity 108 below the thinned portion 110 is preferably a tube or tubular and encircles or encloses a perimeter 114, which is provided with a radius where the wall defining the tubular cavity 108 meets the thinned portion 110 to reduce stress concentrations.
The MEMS silicon pressure sensing element 112 is essentially centered above the perimeter 114. The MEMS silicon pressure sensing element 112 is attached to the top 116 of the port 102 by a glass frit 118. The glass frit 118 bonds or attaches the MEMS pressure sensing element 112 to the top surface 116 such that deflection of the thinned area 110 causes the MEMS silicon pressure sensing element to change its size and shape. When the size and shape of the piezoresistors embedded in the sensing element 112 changes, their resistance values also change, causing an output voltage from the sensing element 112 to change proportionately to the deflection of the thinned area 110.
The port 102 is surrounded by a plastic spacer 120, on top of which is a conventional printed circuit board (PCB) 122. The PCB 122 is attached to the spacer 120 by an adhesive 124. The PCB 122 supports an application-specific integrated circuit (ASIC) 130.
On the left side of
The metal from which the port 102 is made and the material from which the PCB 122 is made, have significantly different coefficients of thermal expansion. (CTE). The coefficients of thermal expansion of the glass frit 118 and MEMS pressure sensing element 112 are also significantly different from the coefficient of thermal expansion for the metal port 102. The mismatches between the CTEs create thermally-induced stresses and voltage noise. In addition to thermally-induced stresses and voltage noise, a threaded connection is difficult to seal hermetically. Reducing or eliminating the mismatch between coefficients of thermal expansions and simplifying the packaging would be an improvement over the prior art.
The pressure sensor device 200 comprises the ceramic circuit board 202 having a top side 204 and a bottom side 206. As can be seen in
The thinned area 210 deflects responsive to pressure changes in the cavity 208 and thus behaves as a diaphragm. The thinned area 210 is therefore considered herein to be a diaphragm 210.
The cavity 208 is essentially a tube that is open on one end, i.e., at the bottom side 206 of the ceramic circuit board 202, and which extends part way through the ceramic circuit board 202 to the thinned area 210. The diaphragm 210 of the embodiment shown in
Pressure is applied to the bottom side 213 of the diaphragm 210 by fluid provided into the cavity 208 by a conduit shown in cross section in
An application-specific integrated circuit (ASIC) 221 is attached to the top side 204 of the ceramic circuit board 202 by an adhesive 222, either a soft mount or a hard mount. The ASIC 220 communicates with the MEMS element 218, i.e., sends electrical signals to and receives electrical signals from the MEMS element 218, through bond wires 224.
Signals to and from the ASIC 221 are filtered by capacitors 226 attached to conductive bond pads 228A-228C by an electrically conductive adhesive (ECA) or solder 230. The capacitors 226 are thus electrically coupled to the ASIC 221. Bond wires 225 electrically interconnect the ASIC 221 to the bond pads 228A-C and connect the ASIC 221 to the capacitors 226 for electromagnetic control (EMC).
The device 300 shown in
A substantially square-shaped seal 330 in
As explained below, the cavity 308 and the square seal 330 are sized, shaped and arranged to receive a conduit that carries a pressurized fluid. An adhesive, such as solder, placed between the square seal 330 and such a conduit acts as a sealant. The square seal 330 is thus considered to be a hermetic soldered seal, which is a device that prevents pressurized fluid or fuel leakage. Pressurized fluid can thus be provided into the cavity 308, which will cause a thinned area 310, i.e., an area at “top” of the cavity referred to herein as a diaphragm, to deflect. Deflection of the diaphragm 310 thus causes a MEMS pressure sensing element 312 to produce an output voltage, which changes in magnitude responsive to deflection of the diaphragm 310.
As can be seen in
On the left side of
The ceramic circuit board in
As can be seen in
Regardless of whether the ceramic is a low temperature or high temperature fired ceramic, and regardless of the shape of the openings in the layers, the multiple layers of ceramic material are heated to a temperature at which the various layers fuse together and become a single monolithic ceramic layer. In the embodiment shown in
A conduit port 604, which extends into the cavity 208 of the pressure sensor device 200, carries pressurized fluid 602 into the cavity 208 and against the ceramic diaphragm 210. The metal ring 240 located in either a recess formed in the or on the surface of the bottom side 206 of the ceramic circuit board 202 is sealed and bonded to the port 604 by either an adhesive or solder 610. Additionally, metallization areas 242 on the perimeter of ceramic circuit board 202 allow solder 612 for attachment to metal conduit 600 for additional support.
The embodiment shown in
The prior art shown in
The foregoing description is for purposes of illustration only. The true scope of the invention is set forth in the following claims.
Chiou, Jen-Huang Albert, Lin, Benjamin C., Vine, Eric Matthew
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Jun 13 2016 | CHIOU, JEN-HUANG ALBERT | Continental Automotive Systems, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 038910 | /0418 | |
Jun 13 2016 | LIN, BENJAMIN C | Continental Automotive Systems, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 038910 | /0418 | |
Jun 13 2016 | VINE, ERIC MATTHEW | Continental Automotive Systems, Inc | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 038910 | /0418 | |
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Aug 10 2021 | Continental Automotive Systems, Inc | Vitesco Technologies USA, LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058108 | /0319 |
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